The invention relates to the temperature control of areas in buildings such as rooms in offices, hotels, retail shops, supermarkets, hospitals, and the like. In particular the invention relates to the cooling of rooms by transfer of heat from the air in the room by means of ceiling structure suspended below the top surface of the room.

It is known to suspend a ceiling structure below the top surface of the room, the structure comprising panels incorporating pipes containing a fluid medium typically water. Heat is transferred from the hot air in the room into the pipes and extracted from the room, to keep the temperature in the room below a predetermined limit. This system has several drawbacks.

It is one object of this invention to provide a suspended ceiling which is more efficient and advantageous in controlling the climate of a room.

In one aspect the invention provides a building including a room having a top surface, a ceiling suspended by hanger means below the top surface, the ceiling comprising one or more panels containing a fluid medium, characterised in that the fluid medium

is in contact with substantially all of the lower surface of the panels whereby heat transfer occurs over substantially all of the lower surface.

Preferably the lower surface of the panels is in direct contact with the air of the room. As a result there is a direct transfer of heat from the air into the fluid medium.

Preferably the lower surface of the panels is contoured to increase the surface area thereof. This may be by suitable shaping and/or the lower surface may be covered with a paint or the like to provide a textured finish.

Preferably the panels include flow control means to distribute the fluid evenly therethrough from an inlet to an outlet. Preferably the inlet and the outlet are set at opposite sides of the panel, e.g. diagonally, or in whichever way is efficient for making connections between the panels making up the ceiling.

The panels may be made of metal, or plastics, or plastics covered sheet metal. Preferably they are moulded of polycarbonate, PVC- u, ABS, high impact styrene or polymethylmethacrylate or any suitable plastic which is inflammable. The mechanical strength of the material forming the panel walls is selected so that the panels can support their own weight and that of the fluid medium without distortion. Preferably in the case of plastics the

panels are made of a material having a tensile strength at 23°C of about 60 MPa and a flexural strength of about 90 MPa; these values will be higher where the panels are made of metal.

The panels may have one wall made of metal for strength, e.g. a plastic coated steel sheeting. Extra layers may be present, e.g. heat insulating layers. A finish may be applied to the panels after moulding, e.g. a paint layer especially of a textured paint, as that will increase the surface area and avoid zones where there is such a temperature difference that condensation can occu .

The panels may be moulded in such a way that there is no need to use T-bars to form a ceiling grid. Thus hook means may be present on the panels and connected to the hanger means whereby the panels are suspended directly from the hanger means. Also, adjacent panels may be shaped so that the lower surface thereof provides a substantially continuous surface.

In one embodiment of the invention the ceiling constitutes the lower wall of a building services duct. In such a case an inlet for fresh air may be present in the duct and the ceiling panels of the invention are arranged to transfer heat to the incoming air from the upper surface thereof.

Preferably the fluid medium comprises water which may contain

additives such as dyes, anti-freeze agents, agents against bacteria and other organisms; and the like.

In another aspect the invention provides a method of cooling a room in a building, the room containing a ceiling suspended by hanger means below the top surface of the room, the ceiling comprising one or more panels through which a fluid medium is passed characterised by contacting the fluid medium with substantially all of the lower surface of the panel.

The method preferably includes the step of locating flow control means in the panel to distribute the fluid evenly in a path from an inlet of the panel to an outlet thereof.

Most preferably the fluid medium is passed under a pressure of less than about 1 bar, particularly about 0.2 bar.

In yet another aspect the invention provides for use in a suspended ceiling, a panel formed of a plastics material and having means for the flow of fluid medium therethrough, characterised in that the panel is shaped so that, in use, the fluid medium is in contact with substantially all of the lower surface of the panel.

Preferably the panel includes means to guide the flow of the fluid medium through the panel from an inlet to an outlet.

Preferably the panel is formed of a material which has sufficient mechanical strength to support the weight of the panel and the fluid medium without distortion. Most preferably the panel includes hook means for direct connection to hanger means.

In order that the invention may be well understood it will now be described with reference to the accompanying diagrammatic drawings, in which:

Figure 1 is a vertical section of one room;

Figure 2 a plan view of one panel of the ceiling of Figure i;

Figures 3 and 4 show respectively a vertical section and a transverse section through the ceiling panel of Figure 2;

Figures 5 and 6 shows respectively a vertical section and a transverse section through another ceiling panel of the invention; and

Figure 7 is a partial elevation of two panels of th invention.

A room R contains a ceiling C suspended from the top surface T o the room, e.g. an overlying floor or the roof of the building.

The ceiling C is made up of panels P located in the squares of a grid frame defined by T bars 2 which are connected to hanger rods 1 secured to the top surface T of the room. The space from the surface T to the top of the ceiling 1 defines a building services space 6, which, as shown includes an inlet 3 in the outer wall 4 and contains a filter 7; at least one grid outlet 5 is present in the ceiling C to draw air from the duct 6 into the space of the room R. (The space 6 is an optional feature) .

Each panel P comprises a lower wall 10 and an upper wall 11 which are sealed at their margins 12 to form a slab like structure. A fluid medium, W, typically water, is present in the panel and enters via an inlet 13 and exits via an outlet 14. The water is supplied via pipes and pumps etc. not shown. It will be clear from the shape of the panel that the water W is in contact with all of the lower surface 10 so that an effective heat transfer can take place between the heat in the air of the room R and the flowing water . As shown in Figure 1, the panels P are empty but as shown in the embodiments of Figure 3 and in Figure 5 the panels may have internal structures to guide the water flow so that it is spread evenly across the panels. Thus in the embodiment of Figures 3 and 4 the upper wall 12 is formed with interior baffles 15 arranged in say a herringbone pattern as seen in plan view, to cause the water W to spread evenly thinly over the lower surface 10. In the embodiment of Figures 5 and 6 the inlet is set at one end of a pipe 16 the longer side of which has

perforations 17 to release small diameter parallel streams. As a result of these structures the heat transfer from air to water is very efficient, and there is little or no heat difference across the panel.

In the embodiment of Figure 7, there are two panels Pi, which at one end, the left hand end, as shown, have a projecting ledge or shoulder 18 and at the other a recess 19, dimensioned so that they can be abutted and present a continuous appearance. The top wall 11 has an end upper hook 20 which engages the end of a hanger rod 1. As a result of this arrangement the T bars 2 and the ceiling grid can be avoided, which saves a substantial proportion of the installation materials and time otherwis required.

A panel of the invention preferably has a thickness from abou 6mm to about 12mm. The structure is made of material which ha mechanical strength so that it can support its own weight and th weight of the water and is shaped so that substantially all o the top and bottom surfaces are exposed to air to provide hea transfer. Typically 80% or more of the energy transfer is b heat radiation and 20% or less by heat convention. Typically th water in a panel is at a pressure of 1 bar or less, preferably o about 0.2 bar, (which is much less than the pressurised water i say a floor or wall mounted central heating system). In the cas of a plastics panel of the invention the energy transfer range

from about 60 to about 150 W/m ² . The air is relatively still and not dried out.

The heat in the water may be extracted for use (or storage) in a suitable medium. It may however be used to heat air, e.g. incoming air in the duct 6.

Because the invention works by extracting heat from a room without causing extraction of the moisture at the same time, it provides an efficient method of controlling indoor climates without affecting the humidity. Because there is no need for much air replacement it is particularly suitable for sterile areas, e.g. hospital operating theatres. The apparatus is silent in use and environmentally acceptable.

The invention is not limited to the embodiment shown. For example the panels can be moulded to the shape of the room and need not be rectangular as seen in plan.